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SAMANTHA GORHAMFRANK H. MORRELL CAMPUS
ADVISOR:
Prof. TREVOR A. TYSON (NJIT)
� I WANT TO THANK PROFESSOR TREVOR A. TYSON FOR HIS HELP IN ASSISTING ME
THROUGHOUT THE COURSE OF THIS PRJECT AND RESEARCH. I ALSO WANT TO
THANK EVERYONE ELSE WHO CONTRIBUTED IN ANY WAY.
~ THANK YOU
� Superconductivity is the loss of all resistance to the passage of an electric current in certain metals and alloys at low temperatures.
� In some of the new classes of ceramic compounds such as YBa2Cu3O6+x (YBCO), superconductivity occurs at significantly higher temperatures.
YBCO crystallizes in a distorted, oxygen-deficient, multi-layered, perovskitestructure. The boundary of each layer is defined by planes of square planar CuO4units sharing 4 vertices. The planes can some times be slightly puckered. Perpendicular to these CuO2planes is CuO4 ribbons sharing 2 vertices. The yttrium atoms are found between the CuO2 planes, while the barium atoms are found between the CuO4ribbons and the CuO2 planes.
� Superconducting Quantum Interference Devices (SQUIDs)
� Magnet Shielding� Nuclear Magnetic Resonance (NMR)
� Magnetic Levitation Trains� Power Generation
� Sensors� Transmission
� Energy Storage
X-ray diffraction (XRD) is the scattering of x-rays as they interact with the periodic atomic structure of solid matter. Each crystalline compound has a distinct x-ray pattern. The role of x-rays in diffraction experiments is based on the electromagnetic properties of this form of radiation. X-ray can be considered a light but with a very short wavelength. The wavelength is comparable to the inter-atomic distance producing a diffraction pattern by interference of scattered waves.
There are two main techniques used for finding the diffraction patterns of different materials.
These techniques are:
SINGLE-CRYSTAL METHODS:
� This is a method in which an x-ray beam is focused on a single crystal.
� The primary application of this method is to determine the atomic structure, symmetry, unit cell dimensions, etc.
POWDER METHODS:
� This is a method in which an x-ray beam is focused on a powder sample composed of small particles. This method is essential for materials that do not form large crystals and it also eliminates the problem of the precise orientation that is needed in the single-methods.
� The primary application of this method is for mineral identification. It can also be used to determine mineral composition along with the relative proportions of minerals in a mixture.
� PROS of XRD:� The significant
penetration ability� During preparation, the
creation of thin sections is often avoidable
� A quick and easy way to observe and characterized known, as well as unknown materials
� CONS of XRD:� The inability to provide real-
space images of the material under investigation
� The inability to provide quantitative compositional data obtained by the electron microprobe or the textural and quantitative compositional data obtained by the scanning electron microscope
� A diffractometer is a measuring instrument used to make a diffraction pattern of any crystalline solid. With a diffraction pattern an observer can identify an unknown mineral, or characterize the atomic-scale structure of an already identified mineral. The typical diffractometer consists of a source of radiation, a monochromator to choose the wavelength, slits to adjust the shape of the beam, a sample and a detector.
It was derived by the English physicists Sir W. H. Bragg and his son Sir W. L. Bragg in 1913 to explain why the cleavage faces of crystals appear to reflect x-ray beams at certain angles of incidence (theta, Θ). They found that substances whose macroscopic forms were crystalline, gave characteristic patterns of reflected X-radiation. These patterns are unlike those produced by liquids. This observation is an example of x-ray wave interference, or XRD. It was direct evidence of the periodic atomic structure of crystals. The Braggs were awarded the Nobel Prize in Physics in 1915 for their work in determining crystal structures.
When certain geometric requirements are met, x-rays scattered from a crystalline solid can constructively interfere, producing a diffracted beam. Bragg recognized a predictable relationship among several factors. These factors include:
� The distance between similar atomic planes in a mineral, or the d-spacing and measure in angstroms
� The angle of diffraction which we call the theta angle and measure in degrees (Because the diffractometer measures an angle twice that of the theta angle, we call the measured angle 2Θ)
� The wavelength of the incident x-radiation (Lambda)
� First, you must obtain the correct ratio measurements of your starting ingredients, (Yttrium Oxide (Y2O3), Barium Carbonate (BaCO3), and Copper Oxide (CuO)) in grams.
� Grind and mix all ingredients together gradually with a mortar and pestle. Do this for about 45 min. or until mixture is a uniform gray color.
� Heat mixture in alumina boat at a temp. of 950 °C for about 16 hours. (Grind and heat – repeat 2 more times, 3 time in all).
� When mixture is completely black it can then be pressed into a pellet.
PROS of SOLID PHASE
METHOD:
� This method allows the material to be heated to
the required temperature of 950 °C
CONS of SOLID PHASE
METHOD:
� Large particle size� The lack of reproductively
� The need for long heat treatment
� XRD tests are run on YBCO sample� A print out of a raw data report is provided,
then organized� HKL measurements are determined� C Language Programming is utilized and an
output of data is generate� Collected data is made into an graph displaying
XRD pattern� All data is combined into a chart, including all
experimental and calculated data
YBCO XRD Plot
0
500
1000
1500
2000
2500
3000
3500
4000
10 20 30 40 50 60 70 80 90 100 110 120
Two-Theta (Deg)
Inte
ns
ity
(C
ou
nts
)
CALCULATIONSCALCULATIONSCALCULATIONSCALCULATIONS:d002 = 5.8478 = c/2� c1 = 11.6956 Å
d005 = 2.2339 = c /5� c2 = 11.1695 Å (outlier)
d006 = 1.9474 = c /6� c3 = 11.6844 Å
d003 = 3.8981 = c/3� c4 = 11.6943Å
C AverageC AverageC AverageC Average = 11.69143333 ÅTo measure the dispersion of a set of values the method of standard deviation we used.STANDARD DEVIATION FORMULA:STANDARD DEVIATION FORMULA:STANDARD DEVIATION FORMULA:STANDARD DEVIATION FORMULA:
We applied this formula to each of the c values we calculated. When we were done, these were the values we obtained.STANDARD DEVIATIONSTANDARD DEVIATIONSTANDARD DEVIATIONSTANDARD DEVIATION:Original numbersOriginal numbersOriginal numbersOriginal numbers:11.6956 Å11.6844 Å11.6943 Å
0.00003 ÅVariance (Population StandardDeviation)
0.005 ÅPopulation Standard Deviation
0.00004 ÅVariance (Standard Deviation)
0.00613 ÅSTANDARD DEVIATION
11.69143 ÅMEAN (AVERAGE)
3TOTAL
This basically explains to you that the c axis is equal to 11.69143 Å ± 0.00613 Å.
Oxygen Content from C-Axis
--15405557577090Tc (K)
11.77111.7611.75111.74711.72911.72811.70611.68c
3.873.87363.87643.87783.88083.88513.88753.8872b
3.8513.84683.84333.84153.83623.83493.82753.8227a
0.380.410.450.480.550.600.730.93x
0.620.590.550.520.450.40.270.07δ
Summary
� Bulk sample of YBCO were synthesized by solid state reaction
� X-Ray diffraction measurements were used to determine the phases present
� No significant impurity levels were observed� Simulations were used to index all major peaks
(C-Program written)� Oxygen content was determined for c-
parameters� Comparisons with RAMAN and Resistivity
show that oxygen content was x~0.9
References
� G. Aleco, Crystal Structures of Some High Temperature (2004)
� H. Altenburg, J. Plewa, W. Jaszczuk, Superconducting Materials for Electric Applications (2002)
� Superconductors (Ramanian Reports in Physics), Vol. 56 No. 3.� R. Cava et al., Phys. Rev. Lett. 58, 1676 (1987).� R. Escudero, The Superconducting Ceramics of High
Temperature (2000)
� J. C. Jackson, X-ray Powder Diffraction, (1997)� J. D. Jorgensen et al., Phys. Rev. B 41, 1863 (1990).� K. S. Martirosyan, E. Galstyan, The Fabrication of YBCO
Superconductor Polycrystalline Powder by CCSO (2008)
� C. M. Pegrum, (N.D.), Microwave Applications of High Temperature Superconductors Based on the Josephson Effect and Tunneling
� T. A. Vanderah, Chemistry of Superconductor Materials (1992)